/* SPU2-X, A plugin for Emulating the Sound Processing Unit of the Playstation 2
 * Developed and maintained by the Pcsx2 Development Team.
 *
 * Original portions from SPU2ghz are (c) 2008 by David Quintana [gigaherz]
 *
 * SPU2-X is free software: you can redistribute it and/or modify it under the terms
 * of the GNU Lesser General Public License as published by the Free Software Found-
 * ation, either version 3 of the License, or (at your option) any later version.
 *
 * SPU2-X is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
 * without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
 * PURPOSE.  See the GNU Lesser General Public License for more details.
 *
 * You should have received a copy of the GNU Lesser General Public License
 * along with SPU2-X.  If not, see <http://www.gnu.org/licenses/>.
 */

#include "Global.h"

const char *ParamNames[8] = {"VOLL", "VOLR", "PITCH", "ADSR1", "ADSR2", "ENVX", "VOLXL", "VOLXR"};
const char *AddressNames[6] = {"SSAH", "SSAL", "LSAH", "LSAL", "NAXH", "NAXL"};

__forceinline void _RegLog_(const char *action, int level, const char *RName, u32 mem, u32 core, u16 value)
{
    if (level > 1)
        FileLog("[%10d] SPU2 %s mem %08x (core %d, register %s) value %04x\n",
                Cycles, action, mem, core, RName, value);
}

#define RegLog(lev, rname, mem, core, val) _RegLog_(action, lev, rname, mem, core, val)

void SPU2writeLog(const char *action, u32 rmem, u16 value)
{
    if (!IsDevBuild)
        return;

    //u32 vx=0, vc=0;
    u32 core = 0, omem, mem;
    omem = mem = rmem & 0x7FF; //FFFF;
    if (mem & 0x400) {
        omem ^= 0x400;
        core = 1;
    }

    if (omem < 0x0180) // Voice Params (VP)
    {
        const u32 voice = (omem & 0x1F0) >> 4;
        const u32 param = (omem & 0xF) >> 1;
        char dest[192];
        sprintf(dest, "Voice %d %s", voice, ParamNames[param]);
        RegLog(2, dest, rmem, core, value);
    } else if ((omem >= 0x01C0) && (omem < 0x02E0)) // Voice Addressing Params (VA)
    {
        const u32 voice = ((omem - 0x01C0) / 12);
        const u32 address = ((omem - 0x01C0) % 12) >> 1;

        char dest[192];
        sprintf(dest, "Voice %d %s", voice, AddressNames[address]);
        RegLog(2, dest, rmem, core, value);
    } else if ((mem >= 0x0760) && (mem < 0x07b0)) {
        omem = mem;
        core = 0;
        if (mem >= 0x0788) {
            omem -= 0x28;
            core = 1;
        }
        switch (omem) {
            case REG_P_EVOLL:
                RegLog(2, "EVOLL", rmem, core, value);
                break;
            case REG_P_EVOLR:
                RegLog(2, "EVOLR", rmem, core, value);
                break;
            case REG_P_AVOLL:
                if (core) {
                    RegLog(2, "AVOLL", rmem, core, value);
                }
                break;
            case REG_P_AVOLR:
                if (core) {
                    RegLog(2, "AVOLR", rmem, core, value);
                }
                break;
            case REG_P_BVOLL:
                RegLog(2, "BVOLL", rmem, core, value);
                break;
            case REG_P_BVOLR:
                RegLog(2, "BVOLR", rmem, core, value);
                break;
            case REG_P_MVOLXL:
                RegLog(2, "MVOLXL", rmem, core, value);
                break;
            case REG_P_MVOLXR:
                RegLog(2, "MVOLXR", rmem, core, value);
                break;
            case R_IIR_VOL:
                RegLog(2, "IIR_VOL", rmem, core, value);
                break;
            case R_COMB1_VOL:
                RegLog(2, "COMB1_VOL", rmem, core, value);
                break;
            case R_COMB2_VOL:
                RegLog(2, "COMB2_VOL", rmem, core, value);
                break;
            case R_COMB3_VOL:
                RegLog(2, "COMB3_VOL", rmem, core, value);
                break;
            case R_COMB4_VOL:
                RegLog(2, "COMB4_VOL", rmem, core, value);
                break;
            case R_WALL_VOL:
                RegLog(2, "WALL_VOL", rmem, core, value);
                break;
            case R_APF1_VOL:
                RegLog(2, "APF1_VOL", rmem, core, value);
                break;
            case R_APF2_VOL:
                RegLog(2, "APF2_VOL", rmem, core, value);
                break;
            case R_IN_COEF_L:
                RegLog(2, "IN_COEF_L", rmem, core, value);
                break;
            case R_IN_COEF_R:
                RegLog(2, "IN_COEF_R", rmem, core, value);
                break;
        }
    } else if ((mem >= 0x07C0) && (mem < 0x07CE)) {
        switch (mem) {
            case SPDIF_OUT:
                RegLog(2, "SPDIF_OUT", rmem, -1, value);
                break;
            case SPDIF_IRQINFO:
                RegLog(2, "SPDIF_IRQINFO", rmem, -1, value);
                break;
            case 0x7c4:
                if (Spdif.Unknown1 != value)
                    ConLog("* SPU2-X: SPDIF Unknown Register 1 set to %04x\n", value);
                RegLog(2, "SPDIF_UNKNOWN1", rmem, -1, value);
                break;
            case SPDIF_MODE:
                if (Spdif.Mode != value)
                    ConLog("* SPU2-X: SPDIF Mode set to %04x\n", value);
                RegLog(2, "SPDIF_MODE", rmem, -1, value);
                break;
            case SPDIF_MEDIA:
                if (Spdif.Media != value)
                    ConLog("* SPU2-X: SPDIF Media set to %04x\n", value);
                RegLog(2, "SPDIF_MEDIA", rmem, -1, value);
                break;
            case 0x7ca:
                if (Spdif.Unknown2 != value)
                    ConLog("* SPU2-X: SPDIF Unknown Register 2 set to %04x\n", value);
                RegLog(2, "SPDIF_UNKNOWN2", rmem, -1, value);
                break;
            case SPDIF_PROTECT:
                if (Spdif.Protection != value)
                    ConLog("* SPU2-X: SPDIF Copy set to %04x\n", value);
                RegLog(2, "SPDIF_PROTECT", rmem, -1, value);
                break;
        }
        UpdateSpdifMode();
    } else {
        switch (omem) {
            case REG_C_ATTR:
                RegLog(4, "ATTR", rmem, core, value);
                break;
            case REG_S_PMON:
                RegLog(1, "PMON0", rmem, core, value);
                break;
            case (REG_S_PMON + 2):
                RegLog(1, "PMON1", rmem, core, value);
                break;
            case REG_S_NON:
                RegLog(1, "NON0", rmem, core, value);
                break;
            case (REG_S_NON + 2):
                RegLog(1, "NON1", rmem, core, value);
                break;
            case REG_S_VMIXL:
                RegLog(1, "VMIXL0", rmem, core, value);
            case (REG_S_VMIXL + 2):
                RegLog(1, "VMIXL1", rmem, core, value);
                break;
            case REG_S_VMIXEL:
                RegLog(1, "VMIXEL0", rmem, core, value);
                break;
            case (REG_S_VMIXEL + 2):
                RegLog(1, "VMIXEL1", rmem, core, value);
                break;
            case REG_S_VMIXR:
                RegLog(1, "VMIXR0", rmem, core, value);
                break;
            case (REG_S_VMIXR + 2):
                RegLog(1, "VMIXR1", rmem, core, value);
                break;
            case REG_S_VMIXER:
                RegLog(1, "VMIXER0", rmem, core, value);
                break;
            case (REG_S_VMIXER + 2):
                RegLog(1, "VMIXER1", rmem, core, value);
                break;
            case REG_P_MMIX:
                RegLog(1, "MMIX", rmem, core, value);
                break;
            case REG_A_IRQA:
                RegLog(2, "IRQAH", rmem, core, value);
                break;
            case (REG_A_IRQA + 2):
                RegLog(2, "IRQAL", rmem, core, value);
                break;
            case (REG_S_KON + 2):
                RegLog(1, "KON1", rmem, core, value);
                break;
            case REG_S_KON:
                RegLog(1, "KON0", rmem, core, value);
                break;
            case (REG_S_KOFF + 2):
                RegLog(1, "KOFF1", rmem, core, value);
                break;
            case REG_S_KOFF:
                RegLog(1, "KOFF0", rmem, core, value);
                break;
            case REG_A_TSA:
                RegLog(2, "TSAH", rmem, core, value);
                break;
            case (REG_A_TSA + 2):
                RegLog(2, "TSAL", rmem, core, value);
                break;
            case REG_S_ENDX:
                //ConLog("* SPU2-X: Core %d ENDX cleared!\n",core);
                RegLog(2, "ENDX0", rmem, core, value);
                break;
            case (REG_S_ENDX + 2):
                //ConLog("* SPU2-X: Core %d ENDX cleared!\n",core);
                RegLog(2, "ENDX1", rmem, core, value);
                break;
            case REG_P_MVOLL:
                RegLog(1, "MVOLL", rmem, core, value);
                break;
            case REG_P_MVOLR:
                RegLog(1, "MVOLR", rmem, core, value);
                break;
            case REG_S_ADMAS:
                RegLog(3, "ADMAS", rmem, core, value);
                //ConLog("* SPU2-X: Core %d AutoDMAControl set to %d\n",core,value);
                break;
            case REG_P_STATX:
                RegLog(3, "STATX", rmem, core, value);
                break;
            case REG_A_ESA:
                RegLog(2, "ESAH", rmem, core, value);
                break;
            case (REG_A_ESA + 2):
                RegLog(2, "ESAL", rmem, core, value);
                break;
            case REG_A_EEA:
                RegLog(2, "EEAH", rmem, core, value);
                break;

#define LOG_REVB_REG(n, t)                  \
    case R_##n:                             \
        RegLog(2, t "H", mem, core, value); \
        break;                              \
    case (R_##n + 2):                       \
        RegLog(2, t "L", mem, core, value); \
        break;

                LOG_REVB_REG(APF1_SIZE, "APF1_SIZE")
                LOG_REVB_REG(APF2_SIZE, "APF2_SIZE")
                LOG_REVB_REG(SAME_L_SRC, "SAME_L_SRC")
                LOG_REVB_REG(SAME_R_SRC, "SAME_R_SRC")
                LOG_REVB_REG(DIFF_L_SRC, "DIFF_L_SRC")
                LOG_REVB_REG(DIFF_R_SRC, "DIFF_R_SRC")
                LOG_REVB_REG(SAME_L_DST, "SAME_L_DST")
                LOG_REVB_REG(SAME_R_DST, "SAME_R_DST")
                LOG_REVB_REG(DIFF_L_DST, "DIFF_L_DST")
                LOG_REVB_REG(DIFF_R_DST, "DIFF_R_DST")
                LOG_REVB_REG(COMB1_L_SRC, "COMB1_L_SRC")
                LOG_REVB_REG(COMB1_R_SRC, "COMB1_R_SRC")
                LOG_REVB_REG(COMB2_L_SRC, "COMB2_L_SRC")
                LOG_REVB_REG(COMB2_R_SRC, "COMB2_R_SRC")
                LOG_REVB_REG(COMB3_L_SRC, "COMB3_L_SRC")
                LOG_REVB_REG(COMB3_R_SRC, "COMB3_R_SRC")
                LOG_REVB_REG(COMB4_L_SRC, "COMB4_L_SRC")
                LOG_REVB_REG(COMB4_R_SRC, "COMB4_R_SRC")
                LOG_REVB_REG(APF1_L_DST, "APF1_L_DST")
                LOG_REVB_REG(APF1_R_DST, "APF1_R_DST")
                LOG_REVB_REG(APF2_L_DST, "APF2_L_DST")
                LOG_REVB_REG(APF2_R_DST, "APF2_R_DST")

            default:
                RegLog(2, "UNKNOWN", rmem, core, value);
                spu2Ru16(mem) = value;
        }
    }
}
